Enhanced DRAM with embedded registers

ABSTRACT

An enhanced DRAM contains embedded row registers in the form of latches. The row registers are adjacent to the DRAM array, and when the DRAM comprises a group of subarrays, the row registers are located between DRAM subarrays. When used as on-chip cache, these registers hold frequently accessed data. This data corresponds to data stored in the DRAM at a particular address. When an address is supplied to the DRAM, it is compared to the address of the data stored in the cache. If the addresses are the same, then the cache data is read at SRAM speeds. The DRAM is decoupled from this read. The DRAM also remains idle during this cache read unless the system opts to precharge or refresh the DRAM. Refresh or precharge occur concurrently with the cache read. If the addresses are not the same, then the DRAM is accessed and the embedded register is reloaded with the data at that new DRAM address. Asynchronous operation of the DRAM is achieved by decoupling the row registers from the DRAM array, thus allowing the DRAM cells to be precharged or refreshed during a read of the row register.

The present application is a continuation of U.S. patent applicationSer. No. 09/182,994, filed Oct. 30, 1998, now U.S. Pat. No. 6,347,357which is a continuation of U.S. patent application Ser. No. 08/888,371,filed Jul. 3, 1997 (now U.S. Pat. No. 5,887,272), which is acontinuation of U.S. patent application Ser. No. 08/460,665, filed Jun.2, 1995 (now U.S. Pat. No. 5,721,862), which is a continuation of U.S.patent application Ser. No. 08/319,289 filed Oct. 6, 1994 (now U.S. Pat.No. 5,699,317), which is a continuation-in-part of U.S. patentapplication Ser. No. 07/824,211 filed Jan. 22, 1992 (abandoned), all ofwhich applications are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to dynamic random access memory (“DRAM”)and more particularly to an Enhanced DRAM (which we call an “EDRAM”)with embedded registers to allow fast random access to the DRAM whiledecoupling the DRAM from data processing operations.

BACKGROUND OF THE INVENTION

As the computer industry evolves, demands for memory have out-paced thetechnology of available memory devices. One of these demands is highspeed memory compatibility. Thus, in a computer system, such as apersonal computer or other computing system, memory subsystems havebecome an influential component toward the overall performance of thesystem. Emphasis is now on refining and improving memory devices thatprovide affordable, zero-wait-state operations.

Generally, volatile memories are either DRAM or static RAM (“SRAM”).Each SRAM cell includes plural transistors. Typically the data stored ina SRAM cell is stored by the state of a flip-flop formed by some of thetransistors. As long as power is supplied, the flip-flop keeps its data:it does not need refreshing. In a DRAM cell, on the other hand, theretypically is one transistor, and data is stored in the form of charge ona capacitor that the transistor accesses. The capacitor dissipates itscharge and needs to be refreshed.

These two types of volatile memories have respective advantages anddisadvantages. With respect to memory speed, the SRAM is faster than theDRAM due, partially at least, to the nature of the cells. Thedisadvantage, however, is that because there are more transistors, theSRAM memory is less dense than a DRAM of the same physical size. Forinstance, static RAMs traditionally have a maximum of one-fourth thenumber of cells of a DRAM which uses the same technology.

While the DRAM has the advantage of smaller cells and thus higher celldensity (and lower cost per bit), one disadvantage is that the DRAM mustrefresh its memory cells whereas the SRAM does not. While the DRAMrefreshes and precharges, access to the memory cells is prohibited. Thiscreates an increase in access time, which drawback the static RAM doesnot suffer.

However, the speed and functionality of current DRAMS are oftenemphasized less than memory size (storage capacity) and cost. This isevidenced by the fact that DRAM storage capacity density has increasedat a rate an order of magnitude greater than its speed. While there hasbeen some improvement in access time, systems using DRAMs generally havehad to achieve their speed elsewhere.

In order to increase system speed, cache memory techniques have recentlybeen applied to DRAM main memory. These approaches have generally beenimplemented on a circuit board level. That is, a cache memory isfrequently a high-speed buffer interposed on the circuit board betweenthe processor chip and the main memory chip. While some efforts havebeen made by others to integrate a cache with DRAM, we first address theboard level approach.

FIG. 1 indicates a prior art configuration (board-level) wherein aprocessor chip 10 is configured with a cache controller 12 and a cachememory 14. The main purpose of the cache memory is to maintainfrequently accessed data for high speed system access. Cache memory 14(sometimes called “secondary cache static RAM”) is loaded via amultiplexer 16 from DRAMs 20, 22, 24 and 26. Subsequently, data isaccessed at high speeds if stored in cache memory 14. If not, DRAMs 20,22, 24 and/or 26 load the sought data into cache memory 14. As seen inFIG. 1, cache memory 14 may comprise a SRAM, which is generally fasterthan DRAMS 20-26.

Various approaches have been proposed for cache memory implementation.These approaches include controlling external cache memory by acontroller, such as cache memory 14 and cache controller 12 in FIG. 1,or discrete proprietary logic. Notwithstanding its benefits, cachememory techniques complicate another major problem that exists in systemdesign. Memory components and microprocessors are typically manufacturedby different companies. This requires the system designer to effectivelybridge these elements, using such devices as the cache controller 12 andthe multiplexer 16 of FIG. 1. These bridge components are usuallyproduced by other companies. The different pin configurations and timingrequirements of these components makes interfacing them with otherdevices difficult. Adding a cache memory that is manufactured by yetanother company creates further design problems, especially since thereis no standard for cache implementation.

Exacerbating the system design problems is the disadvantage that the useof external cache memory (such as cache memory 14) compromises the mainstorage access speed. There are mainly two reasons for this compromise.First, and most significant, the main storage access is withheld until a“cache miss” is realized. The penalty associated with this miss canrepresent up to two wait states for a 50 MHz system. This is in additionto the time required for a main memory access. Second, the prioritizedtreatment of physical routing and buffers afforded the external cache isusually at the expense of the main memory data and address access path.As illustrated in FIG. 1, data from DRAMs 20, 22, 24 and 26 can beaccessed only through cache memory 14. The actual delay may be small,but adds up quickly.

A third problem associated with separate cache and main memory is thatthe time for loading the cache memory from the main memory (“cachefill”) is dependent on the number of inputs to the cache memory from themain memory. Since the number of inputs to the cache memory from themain memory is usually substantially less than the number of bits thatthe cache memory contains, the cache fill requires many clock cycles.This compromises the speed of the system.

A memory architecture that has been used or suggested for video RAMs(“VRAMs”) is to integrate serial registers with a main memory. VRAMs arespecific to video graphics applications. A VRAM may comprise a DRAM withhigh speed serial registers allowing an additional access port for aline of digital video data. The extra memory used here is known as a SAM(serially addressed memory), which is loaded using transfer cycles. TheSAM's data is output by using a serial clock. Hence, access to theregisters is serial, not random. Also, there is continuous access to theDRAM so refresh is not an issue as it is in other DRAM applications.

Another implementation that is expected to come to market in 1992 ofon-chip cache memory will use a separate cache and cache controllersub-system on the chip. It uses full cache controllers and cache memoryimplemented in the same way as it would be if external to the chip, i.e.a system approach. This approach is rather complicated and requires asubstantial increase in die size. Further, the loading time of the cachememory from the main memory is constrained by the use of input/outputcache access ports that are substantially fewer in number than thenumber of cache memory cells. A cache fill in such a manner takes manyclock cycles, whereby system access speed suffers. Such an approach is,in the inventors' views, somewhat cumbersome and less efficient than thepresent invention.

Still another problem in system design arises when the system has both(a) interleaved memory devices together with (b) external cache memory.Interleaving assigns successive memory locations to physically differentmemory devices, thereby increasing data access speed. Such interleavingis done for high-speed system access such as burst modes. The addedcircuitry for cache control and main memory multiplexing usuallyrequired by external cache memory creates design problems for effectiveinterleaved memory devices.

Another problem with the prior art arises when memory capacity is toincrease. Adding more memory would involve adding more external SRAMcache memory and more cache control logic. For example, doubling thememory size in FIG. 1 requires not only more DRAM devices required, butalso another multiplexer and possibly another cache controller. Thiswould obviously add to system power consumption, detract from systemreliability, decrease system density, add manufacturing costs andcomplicate system design.

Another problem concerns the cost of manufacturing a system with anacceptable cache hit probability. When using external cache memory,manufacturers allocate a certain amount of board area for the mainmemory. A smaller area is allocated for the external cache. Usually, itis difficult to increase the main memory and the external cache memorywhile maintaining an acceptable cache hit probability. This limitationarises from the dedication of more board area for the main memory thanfor external cache.

A further problem with system speed is the need for circuitry externalto the main memory to write “post” data. Post data refers to datalatched in a device until it is needed. This is done because the timingrequirement of the component needing the data does not synchronize withthe component or system latching the data. This circuitry usually causestiming delays for the component or system latching the data.

As stated supra, access to the DRAM memory cells during a precharge andrefresh cycle was prohibited in the prior art. Some prior art approacheshave tried to hide the refresh in order to allow access to DRAM data.One DRAM arrangement maintained the data output during a refresh cycle.The drawback of this arrangement was that only the last read data wasavailable during the refresh. No new data read cycle could be executedduring the refresh cycle.

A pseudo-static RAM is another arrangement that attempted to hide therefresh cycle. The device was capable of executing internal refreshcycles. However, any attempted data access during the refresh cyclewould extend the data access time, in a worst case scenario, by a cycletime (refresh cycle time plus read access time). This arrangement didnot allow true simultaneous access and refresh, but used a time divisionmultiplexing scheme to hide the refresh cycle.

Another way to hide the refresh cycle is to interleave the RAM memory onthe chip. When a RAM memory block with even addresses is accessed, theodd memory block is refreshed and vice-versa. This type ofimplementation requires more timing control restraints which translateto a penalty in access time.

Another type of problem arises when considering the type of access modesto the main memory. One type of access is called page mode, in whichseveral column addresses are synchronously applied to an array after arow address has been received by the memory. The output data access timewill be measured from the timing clock edge (where the column address isvalid) to the appearance of the data at the output.

Another type of access mode is called static column mode wherein thecolumn addresses are input asynchronously. Access can occur in thesemodes only when RAS is active (low), and a prolonged time may berequired in the prior art.

When manufacturing chips that support these access types, only one ofthese access types can be implemented into the device. Usually, one ofthe last steps in the making of the memory chip will determine if itwill support either type of access. Thus, memory chips made this way donot offer both access modes. This induces an added expense in that themanufacturer must use two different processes to manufacture the twotypes of chips.

To overcome these problems, small modifications added to a component,such as a DRAM, may yield an increase in system performance andeliminate the need for any bridging components. To successfullyintegrate the modification with the component, however, its benefit mustbe relatively great or require a small amount of die space. For example,DRAM yields must be kept above 50% to be considered producible. Yieldscan be directly correlated to die size. Therefore, any modifications toa DRAM must take into account any die size changes.

In overcoming these problems, new DRAM designs have become significant.The greatest disadvantage to caching within DRAMs has been that DRAMsare too slow. The present invention in one of its aspects seeks tochange the architecture of the DRAM to take full advantage of highcaching speed that may now be obtainable.

One way to meet this challenge is to integrate the functions of the mainstorage and cache. Embedding the cache memory within localized groups ofDRAM cells would take advantage of the chip's layout. This placementreduces the amount of wire (conductive leads) used in the chip which inturn shortens data access times and reduces die size.

U.S. Pat. No. 5,025,421 to Cho is entitled “Single Port Dual RAM.” Itdiscloses a cache with typical DRAM bit lines connected to typical SRAMbit lines through pass gates. Reading and writing the SRAM and DRAMarrays occurs via a single port, which requires that input/output bussescommunicate with the DRAM bit lines by transmitting data through theSRAM bit lines. Using SRAM bit lines to access the DRAM array precludesany access other than refresh to the DRAM array while the SRAM array isbeing accessed, and conversely precludes access to the SRAM array whilethe DRAM array is being accessed, unless the data in the SRAM is thesame data as in the currently accessed DRAM row. This is a functionalconstraint that is disadvantageous.

Moreover, the SRAM cells of Cho FIG. 1 are full SRAM cells, although hisFIG. 4 may disclose using only a single latch (FF11) rather than anentire SRAM cell. However, the use of a single port with a simple latchraises a severe problem. Such an architecture lacks the ability to writedata into the DRAM without corrupting the data in the SRAM latch. Hence,the FIG. 4 configuration is clearly interior to Cho's FIG. 1configuration.

Another effort is revealed by U.S. Pat. No. 4,926,385 to Fujishima,Hidaka, et al., assigned to Mitsubishi, entitled, “Semiconductor MemoryDevice With Cache Memory Addressable By Block Within Each Column.” Thereare other patents along these lines by Fujishima and/or Hidaka. This oneuses a row register like Cho FIG. 4. Two ports are used, but twodecoders are called for. While this overcomes several of the problems ofCho, it requires a good deal more space consumed by the second columndecoder and a second set of input/output switch circuitry. (SubsequentFujishima/Hidaka patents have eliminated the second access port andsecond decoder and have reverted to the Cho FIG. 1 approach, despite itsdisadvantages.) Nevertheless, in this patent, the “tag” and datacoherency control circuitry for the cache is external to the chip and isto be implemented by the customer as part of the system design. The“tag” refers to information about what is in the cache at any givenmoment. A “hit” or “miss” indication is required to be generated in thesystem, external to the integrated circuit memory, and supplied to thechip. This leads to a complicated and slower system.

Other Fujishima, Hidaka, et al. U.S. patents include U.S. Pat. Nos.5,111,386; 5,179,687; and 5,226,139.

Arimoto U.S. Pat. No. 5,226,009 is entitled, “Semiconductor memorydevice supporting cache and method of driving the same.” This detectswhether a hit or miss occurs by using a CAM cell array. The basicarrangement is like the approach of Cho FIG. 1 but modified to collectDRAM data from an “interface driver,” which is a secondary DRAM senseamplifier, rather than from the primary DRAM sense amplifiers. Thisarchitecture still accesses the DRAM bit lines via the SRAM bit linesand is plagued with the single port problem. Circuitry is provided topreserve coherency between the DRAM and the SRAM. A set of tag registersis discussed with respect to a system-level (off-chip) implementation ina prior art drawing. Arimoto implements his on-chip cache tag circuitryusing a content addressable memory array. That approach allows N-waymapping, which means that a group of memory devices in the cache can beassigned to any row in any of N subarrays. For example, if anarchitecture is “4-way associative,” this means that there are four SRAMblocks, any of which can be written to by a DRAM. This method results ina large, expensive, and slow implementation of mapping circuitry. Usinga CAM array for tag control has an advantage of allowing N-wayassociation. However, the advantage of N-way association seems not tooutweigh the disadvantage of the large and slow CAM array to support theN-way SRAM array.

Dye U.S. Pat. No. 5,184,320 is for a “Cached random access memory deviceand system” and includes on-chip cache control. The details of theactual circuitry are not disclosed, however. This patent also isdirected to N-way association and considerable complication is added tosupport this.

Another piece of background art is Matick et al. U.S. Pat. No. 4,577,293for a “Distributed on-chip cache.” It has 2-way associative cacheimplemented using a distributed (on-pitch) set of master-slave rowregister pairs. Full flexibility of access is provided by dual portsthat are not only to the array but also to the chip itself. The twoports are totally independent, each having pins for full address inputas well as data input/output. The cache control is on-chip.

Thus it should be appreciated that the art has heretofore often directedefforts in achieving N-way association. While this has led tocomplications, the art has thought that N-way association is theapproach to follow.

The present invention, according to one of its aspects, rejects thiscurrent thinking and instead provides a streamlined architecture thatnot only includes on-chip cache control, but also operates so fast thatthe loss of N-way association is not a concern.

Therefore, it is a general object of this invention to overcome theabove-listed problems.

Another object of the present invention is to isolate the cache memorydata access operation from undesirable DRAM timing overhead operations,such as refresh and precharge.

A further object of the present invention is to eliminate the need for aexternal static RAM cache memory in high speed systems.

Still another object of the present invention is to insure cache/mainmemory data coherency.

Another object of this invention is to insure such data coherency in afashion which minimizes overhead, so as to reduce any negative impactsuch circuitry might have on the random data access rate.

SUMMARY OF THE PRESENT INVENTION

The present invention provides a high-speed memory device that is hybridin its construction and is well-suited for use in high-speedprocessor-based systems. A preferred embodiment of the present inventionembeds a set of tightly coupled row registers, usable for a static RAMfunction, in a high density DRAM, preferably on the very same chip asthe DRAM array (or subarrays). Preferably, the row registers are locatedwithin or alongside the DRAM array, and if the DRAM is configured withsubarrays, then multiple sets of row registers are provided for themultiple subarrays, preferably one set of row registers for eachsubarray. Preferably the row registers are oriented parallel to DRAMrows (word lines), orthogonal to DRAM columns (bit lines). The rowregisters operate at high speed relative to the DRAM. Preferably thenumber of registers is smaller than the number of bit lines in thecorresponding array or subarray. In the preferred embodiment, one rowregister corresponds to two DRAM bit line pairs, but in otherapplications, one register could be made to correspond to another numberof DRAM bit line pairs. Preferably selection circuitry is included toselect which of the several bit line pairs will be coupled (ordecoupled) from the corresponding row register.

Preferably the row registers are directly mapped, i.e. a one-wayassociative approach is preferred. Preferably the configuration permitsextremely fast loading of the row registers by connecting DRAM bit linesto the registers via pass gates which selectively couple and decouplebit lines (bit line pairs) to the corresponding row registers. Thus, byselecting which bit line pairs are to be given access to the rowregisters, the sense amplifiers for example drive the bit lines to thevoltages corresponding to the data states stored in a decoded row ofDRAM cells and this is loaded quickly into the row registers. Thus, afeature of the present invention is a very quick cache fill.

The fast fill from the DRAM to the row registers provides a verysubstantial advantage. In the case of a read miss, mentioned below, aparallel load to the row registers is executed. Thereafter, each readfrom the same row is a read hit, which is executed at SRAM speeds ratherthan DRAM speeds.

Preferably the row registers are connected to a unidirectional output(read) port, and preferably this is a high impedance arrangement. Thatis, in the preferred embodiment, the registers are not connected to thesource-drain path of the read port transistors, but instead they areconnected to gate electrodes thereof. This leads to improvements in sizeand power.

The DRAM bit lines are preferably connected to a unidirectional input(write) port. In a circuit according to some aspects of the invention,the row registers can be decoupled from the DRAM bit lines and datacould still be inputted to the DRAM bit lines via the write port.Moreover, even when the row registers are decoupled from the DRAM bitlines, data can be read from the row registers.

Preferably both the read and write ports operate off one decoder.

The configuration of an integrated circuit memory according to a relatedaspect of the invention will not require an input/output data bussconnected to the sense amplifiers, since each DRAM subarray will belocated between its corresponding set of row registers and the DRAMsubarray's corresponding set of sense amplifiers, and since the datainput and output functions are executed on the row register side.

In addition to including row registers, preferably in a directly mappedconfiguration, a circuit using the present invention preferablyintegrates simple, fast control circuitry for the cache (registers).Hence the integrated circuit memory device preferably contains on-chipaddress compare circuitry, including at least one “last read row”address latch and an address comparator. Where multiple subarrays areused, multiple sets of row registers are used, each having a respective“last read row” and thus a respective “last read row” register. Addressand data latches, a refresh counter, and various logic for controllingthe integrated circuit memory device also are preferably included on thechip.

Memory reads preferably always occur from the row registers. When anaddress is received by the memory device, the address comparatordetermines whether that address corresponds to an address of the rowthat was last read into the associated row register. When the addresscomparator detects a match (“hit”), only the row register is accessed,and the data stored there is available from the addressed column at SRAMspeeds. Subsequent reads within the row (burst reads, local instructionsor data) will continue at that same high speed.

When a read “miss” is detected, the DRAM main memory is addressed andthe addressed data is written into the row register. In the event ofsuch a “miss,” the first bit of data is available at the output at aslightly slower speed than a hit. Subsequent bits read from the rowregister will have the same extremely fast access as for a hit.

Since the data corresponding to the received address is read from therow register in both cases, and since according to another aspect of theinvention in its preferred form the row register can be decoupled fromthe DRAM, the DRAM precharge can occur simultaneously and asynchronouslywithout degrading overall system performance. The refresh counter and anindependent refresh bus are implemented to allow the main memory (i.e.,the arrayed DRAM cells) to be refreshed during row register reads.

Memory writes are preferably directed toward the main memory. Whenappropriate, i.e., in a “write hit,” the on-chip address comparator willalso activate circuit elements to achieve a simultaneous write to therow registers. In this way, the data in the row register and the data inthe main memory will be coherent for the same address. In a “writemiss,” where data is to be written into DRAM addresses that are not thesame as the “last read row” for that particular DRAM block or subarray,the row register contents need not, and preferably will not, beoverwritten. Moreover, changing rows during memory writes does notaffect the contents of the row register until the row address specifiedwriting becomes the same as the “last read row.” This allows the system(during write misses) to return immediately to the row register whichhad been accessed just prior to the write operation. Write posting canbe executed without external data latches. Page mode memory writes canbe accomplished within a single column address cycle time.

Without initiating a major read or write cycle, the row registers can beread under column address control. It is preferred that the chip isactivated and the output is enabled.

The toggling of the on-chip address latch by the user allows thepreferred embodiment of the present invention to operate in either apage or static column mode. Further, the zero nano-second hold allowsthe /RE signal to be used to multiplex the row and column addresses.

When a read hit occurs on an /RE initiated cycle, the internal rowenable signal is not enabled and a DRAM access does not occur, therebyshortening the cycle time and the precharge required.

A novel and important aspect of the operation of such a DRAM withembedded row registers is the provision of zero-wait state random dataaccesses from the cache memory while the DRAM is being refreshed orprecharged, or otherwise operated asynchronously.

Another salutary aspect of the invention is that within the arraystructure is embedded cache memory that allows quicker cache memory filland optimization of die density.

Another aspect of the invention is the way in which pins are used.Functions heretofore included in /RAS and /CAS have been reassigned toseparate pins for refresh control, output enable control, and chipselection. The control signals /CAS and /RAS are replaced by a columnaddress latch signal /CAL and a row enable signal /RE, each having arespective dedicated pin. This change in pin usage permits fasteroperation.

The invention also includes methods for operating a DRAM with embeddedregisters. A first method of operating the memory device may comprisethe steps of: (1) initiating a major read or write cycle; (2) comparingthe row address with the previous row address to determine whether thesought data is in the cache memory; (3) if in a read cycle, reading thedata from the cache memory if it is stored there or loading the datainto the cache memory from the main memory and then reading the datafrom the cache memory; and (4) if in a write cycle, writing only to themain memory if the data is not in the cache memory or writing to bothmain memory and cache memory if the data is in the cache memory.

A second method for operating the memory device may comprise the stepsof: (1) refreshing a row of main memory; and (2) simultaneously andasynchronously reading the cache memory.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention, together with its objects and the advantages thereof, maybest be understood by reference to the following detailed descriptiontaken in conjunction with the accompanying drawings, of which:

FIG. 1 is a block diagram of the prior art cache implementation showingseveral different chips and circuits;

FIG. 2 is a block diagram showing how a processor may be connected to anenhanced DRAM according to the present invention;

FIG. 3 is a functional block diagram of the enhanced DRAM shown in FIG.2;

FIG. 4 is a detailed block diagram of row address control logiccircuitry of FIG. 3;

FIG. 5 is a detailed block diagram of a column address control circuitcontained in FIG. 3;

FIG. 6 is a detailed diagram of the write load multiplexer and the rowregister of FIG. 3; and

FIG. 7 shows an orientation within a DRAM chip of multiple subarrays andsome associated circuitry from FIG. 3.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The FIG. 2 block diagram shows a CPU (processing unit) 30 preferablyconnected to both control logic circuitry 32 and an EDRAM 34. Each suchcircuit 30, 32, 34 is on a respective integrated circuit (“chip”). Ascan be seen in comparison with FIG. 1, the preferred embodiment of FIG.2 uses only three chips as compared to the eight chips of FIG. 1. ThisFIG. 2 arrangement provides greater system performance, lower systemcost, lower system power requirements, increased system reliability,improved system density, simplified system design and easy memory systemsalability.

Together with external control logic contained in control logic 32,EDRAM 34 of FIG. 2 supplants secondary cache 14, cache controller 12,multiplexer 16 and slow DRAMs 20, 22, 24 and 26 of FIG. 1. The totalmemory capacity of the four slow DRAM chips 20, 22, 24 and 26 can becombined onto one chip without the need for interleaving, thus obviatingmultiplexer 16. Further, EDRAM 34 preferably contains internal cache andcache control logic, thereby obviating secondary cache 14 and portionsof cache controller 12. It will be appreciated therefore that thepresent invention also reduces board space.

With such integration of the various chip functions of the prior art,access to data in cache memory will have a zero wait-state. This fastaccess time will allow data transfer at high speeds (such as done inburst modes) without the need for interleaving or costly external cachememory. In addition, access to the EDRAM is preferably address sequenceindependent. This makes interleaving easier when used with addresssequence dependent modes.

A more detailed description of EDRAM 34 will be discussed with referenceto FIG. 3, which is a functional block diagram. EDRAM 34 preferablyreceives the following input signals on respective pins:

chip select signal /S refresh control signal /F write/read signal W/Rrow enable signal /RE output enable signal /G write enable signal /WEaddress data A₀-A₁₀ column address latch signal /CAL.Output data is illustratively four bits wide. These output bits may usefour pins that can be called DQ0, DQ1, DQ2, and DQ3. The DQ pins may beused to receive input data signals DIN and to provide output data DOUT.

A 4 Mb memory according to the present invention can be arranged in a28-pin package, using the following as illustrative pin assignments:

signal pin signal A0 1 28 Vss A1 2 27 DQ0 A3 3 26 DQ1 A4 4 25 DQ2 A5 524 DQ3 /RE 6 23 /G Vcc 7 22 Vcc Vss 8 21 Vss A6 9 20 /WE A7 10 19 /S A811 18 /F A2 12 17 W/R A9 13 16 /CAL Vcc 14 15 A10

By way of major components, the circuit of FIG. 3 comprises a DRAMsubarray 40. Associated therewith are sense amplifiers 44 coupled to thebit lines 45 in the subarray. At the right side of subarray 40, bitlines 45 (or other conductors) couple data bits to a circuit block, theleft portion of which is a write and load multiplexer 48. The rightportion of this block is a row register 56. FIG. 6 shows this block inschematic form.

FIG. 3 also shows a row decoder/address latch 52 which is coupled via aplurality of leads 53 to DRAM subarray 40.

The row register 56 part of FIG. 3 receives signals from write and loadmultiplexer 48 via transistors shown in FIG. 6. Row register 56 isfurther coupled to receive signals from a column decoder 60 via aplurality of leads 61. Row register 56 outputs signals on leads 57 tooutput data buffers 64, which drive an output bus 65 of the circuit.

A refresh address counter 68 provides a plurality of signals on a bus 69to row decoder and address latch 52. Counter 68 receives a refreshcontrol signal via a lead 70 from row address control logic circuitry72. As will be appreciated, having an on-chip refresh counter 68 andindependent refresh bus 69 will allow the DRAM cells to be refreshedduring cache reads.

An address bus 71 is coupled to several blocks within FIG. 3, includingrow decoder 52, row address control logic 72, column decoder 60, andfurther circuits discussed infra. Address bus 71 illustratively receiveseleven bits of address data A₀-A₁₀. This address data preferablyincludes 11 bits of row data and then 11 further bits of column data, orvice-versa. Alternatively but not preferably, the bus could carry asmaller number of bits of both row and column addresses simultaneously.Another alternative, but not preferred, configuration would provide twoseparate address buses: one for row addresses only and the other forcolumn addresses only.

Address data on bus 71 is also applied to column address control logiccircuitry 76. Also, a one-of-four decoder 82 preferably receives addressdata bits A₉ and A₁₀ from bus 71 and the column address latch signal/CAL (mentioned above as one of the input signals). As noted, addressbus 71 is preferably multiplexed so that it carries row addresses andcolumn addresses at respective times. Column address latch signal /CAL,chip select signal /S, refresh control signal /F, row enable signal /RE,write/read signal W/R, and write enable signal /WE are connected to rowaddress control logic 72.

Row address control logic 72 provides a row address enable signal and arefresh address enable signal on lines 73 and 74, respectively, to rowdecoder circuit 52. Row decoder 52 is coupled to memory array 40, suchas to its word lines, as is well-known. The word lines 53 are preferablyorthogonal to columns (bit lines 45) in memory array 40, which may ormay not contain subarrays. Preferably a group of sense amplifiers 44 areto one side of their corresponding array 40 and the corresponding rowregister 56 is on the opposite side of the array or subarray. Thispositioning of the subarray between its corresponding sense amplifiersand corresponding row registers is seen in FIG. 7 also.

Preferably row register 56 is embedded at the ends of the bit lines 45of subarray 40. This arrangement minimally increases the die size of thepreferred embodiment. Further, as illustrated in FIG. 6, two bit linepairs (bit0 and /bit0, and bit1 and /bit1) are coupled to cross-coupledinverters 142 and 144 of row register 56. It will be appreciated thatsuch cross-coupled inverters comprise a static flip-flop usable as astatic memory cell. This circuit facilitates the extremely fast rowregister 56 fill since each of the inverter pairs, illustrativelyinverters 142 and 144, are selectively coupled to preferably two bitline pairs as will be discussed below. It will be understood that therow register 56 includes a plurality of inverter pairs.

Preferably embedding the row register 56 and sense amplifiers 44 onrespective opposing ends of the DRAM array (or subarray) takes advantageof the impedance of the bit line pairs. This impedance helps maintainthe state of sense amplifiers 44 when an unaltered (masked) writeoperation is performed. A masked write operation is where a memory bitor bits are written with a common mode high level voltage. This voltageon the bit line(s) will not cause the sense amplifiers 44 to toggle.Therefore, when the common mode high level voltage is removed from theintended unaltered bit line(s), the sense amplifier will restore the bitline(s) to the prior state.

It may be noted here that no input/output bus lines are shown to senseamplifiers 44. It will be appreciated from discussions infra that datais written into the DRAM subarray via a dedicated input (write) portillustrated in FIG. 6. A separate output (read) port is shown also inFIG. 6, using a high impedance circuit arrangement.

It will be understood that the symbol “Y” connotes a column or columnsignal, of which there are several types (write, write enable, read,read enable). Multiplexer 48 is preferably coupled to receive (decoded)write enable signals Yw from column decoder 60. Row register 56preferably receives as inputs a plurality of (decoded) column readsignals Yr transmitted on n+1 lines 61 from column decoder 60 via a bus62. Row register 56 outputs data signals D_(out) via bus 57 to outputdata buffer 64. Buffer 64 also preferably receives the output enablesignal /G and a select bus 81 as inputs. Buffers 64 preferably outputthe output data Q on bus 65. Bus 65 is preferably 4-bits wide.

Column address control logic circuit 76 preferably further receives asan input a hit/miss signal transmitted on a line 75 from row addresscontrol logic 72. Control logic 76, as illustrated, outputs aload1/load2 signal to multiplexer 48 via bus 80. Control logic 76 alsopreferably outputs a column read enable /Yre, column write enable /Yweand column address (decode) enable to decoder 60 by way of lines 79, 77and 78, respectively. Inputs to column address control 76 alsopreferably include write enable signal /WE, column address latch signal/CAL, read enable signal /RE, write/read signal W/R and address bit A₁₀preferably of row address data.

Input data DIN conducted on a data input bus 83 is illustratively inputto both a mask latch 84 and a data latch 88. Bus 83 is preferably, butnot limited to, a 4-bit width. Mask latch 84 preferably receives the rowenable signal /RE as an input latch enable. Data latch 88 preferablyreceives the write enable signal /WE as an input latch enable. Theoutputs of both latches 84 and 88 are preferably coupled to a data mask92 along with write enable signal /WE and column address latch signal/CAL. As shown in FIG. 3, data mask 92 is also coupled to receive theoutput of decoder 82 via a bus 81. Bus 81 is preferably 4-bits wide.Column bits A9 and A10 are used by decoder 82. The output of data mask92 is coupled via a bus 94 to a data select circuit 96. Bus 94 is alsopreferably 4-bits wide. Data select circuit 96 is preferably coupledthrough a bus 97, preferably 4-bits wide, to multiplexer 48.

FIG. 4 shows further details of the row address control logic circuitblock 72 of FIG. 3. In FIG. 4, a row comparison register control circuit100 is preferably coupled to receive as inputs the refresh controlsignal /F, column address latch signal /CAL, chip select signal IS,write/read signal W/R and row enable signal /RE. The output of latchcontrol 100 is illustratively connected via a line 101 to one or morelast read row latches 104. Each latch 104 also preferably receives rowaddress data from bus 71. Therefore, each DRAM subarray 40 of the EDRAMwill have a respective last read row latch 104 to store addressinformation identifying the last read row from its corresponding memoryblock. The output of latch 104 is preferably provided via a bus 106 to acomparator 108. Comparator 108 preferably compares two 11-bit addressinputs, one of which is provided by latch 104. The other 11-bit addressinput is received preferably through a bus 109. Comparator 108 generatesa hit/miss signal which is transmitted via line 75 to a row kill circuit112 and column address control logic circuit 76 (FIG. 3).

Row kill circuit 112 preferably receives as inputs write enable signal/WE, chip select signal /S, write/read signal W/R and column addresslatch signal /CAL. It checks the inputs to determine whether a writecycle or a read miss cycle is required. If no such cycle is required, itprovides a row kill signal to a row kill control logic circuit 116 byway of a line 113.

In addition to receiving the row kill signal, control logic 116preferably is coupled to receive row enable signal /RE and refreshcontrol signal /F. Control logic circuit 116 determines from theseinputs whether it should enable the row decoder 52 (FIG. 3) to latcheither the refresh address from refresh counter 68 or the row addressfrom address bus 71. Generally, row enable signal /RE when activesignifies a request from the user (e.g., CPU 30) for access to the DRAMarray 40 (read or write). When refresh control signal /F is active, itsignifies that array 40 is to be refreshed, so row decoder 52 must latchrow refresh address data. However, if the row kill signal is active,then the two outputs from control logic 116 will be inactive, whichkeeps the row decoder 52 from latching any address. Since no row addressis latched or decoded, the memory array 40 is not accessed and there isno destructive read, and no need to initiate precharge or refresh. Theoutputs “row address enable” and “refresh address enable” of controllogic 116 are coupled via lines 73 and 74, respectively, to row decoder52.

FIG. 5 shows further details of the column address control logic circuitblock 76 of FIG. 3. FIG. 5 preferably includes a column kill detectorcircuit 120 which preferably receives the following input signals: rowenable /RE, write/read signal W/R, column address latch signal /CAL andwrite enable /WE. Detector 120 is preferably coupled to provide itsoutput signal, called ColKill, via a line 121 to a column addresscontrol circuit 124. Detector 120 operates in a manner similar to rowkill circuit 112 (FIG. 4). It detects whether a valid read or writecycle has been initiated.

Control circuit 124 also preferably receives the following inputsignals: “hit/miss”, write/read W/R, row enable /RE and column killColKill. From these inputs, control 124 determines whether a column reador column write is to occur. It generates four outputs, of which ROK(“read OK”), /LOAD, and WOK (“write OK”) are coupled to a columnread/write controller 130 by way of lines 126, 127 and 128 as shown inFIG. 5. Preferably line 127 is also connected to a load multiplexercontroller 134. A fourth output COLAE (column address enable) ofcontroller 124 is output over line 78 to column decoder 60 (FIG. 3).

Column read/write controller 130 also receives as further inputs writeenable /WE and /CAL. Controller 130 also preferably outputs /Yre and/Ywe through lines 79 and 77, respectively, to column decoder 60.

Load multiplexer controller 134 preferably receives as inputs addressbit A₁₀ and /RE. The outputs of controller 134, load1 and load2, areillustratively coupled to multiplexer 48 via lines so.

FIG. 6 shows circuit details of part of a row register and itsassociated write and load circuit 48. It will be understood that a DRAMsubarray contains numerous memory cells arranged in rows and columns,and it would be typical for there to be 1,064 columns in each subarray.For reasons that will become apparent, the preferred embodiment usesone-half as many FIG. 6 circuits as there are columns. In FIG. 6, fieldeffect transistors are shown for illustrative purposes. Other types oftransistors or switching devices may be employed. In FIG. 6, a firstpair of complementary bit lines BIT0 and /BIT0, and a second such pairBIT1 and /BIT1 are the bit lines from memory subarray 40 (not shown) ofFIG. 3. In FIG. 3 they are part of lines 45 but in FIG. 6 they arelabeled as lines 45-1, 45-2, 45-3, and 45-4. These bit lines are coupledto an input (write) port formed by write transistors 203, 205, 207, and209 which, when activated by a decoded line, allow input data DIN topass through the write transistors onto the bit lines. Hence the drainsof these four write transistors are coupled to bus 97 (FIG. 3) whichprovides the selected input data. Bus 97 is illustratively composed ofDIN0, /DIN0, DIN1, AND /DIN1. The gate electrodes of the writetransistors 203, 205, 207, and 209 of the input port are coupled to aselected (decoded) line from Yw bus 62.

The bit lines 45-1,2,3,4 are selectively coupled by field effecttransistors 212, 214, 216, and 218 or other switching devices to lines222, 224, 226, and 228, respectively. Lines 222-228 are connected to thestatic RAM latches formed by, e.g., inverter circuits 142, 144 of therow register 56. Transistors 212-218 allow the DRAM bit lines 45-1,2,3,4to be selectively decoupled from lines 222-228 and from the latch. Thus,bit lines from DRAM subarray 40 are preferably coupled to the sources oftransistors 212-218. Preferably, the gate electrodes of transistors 212and 214 are coupled together to receive the signal Load 1. Similarly,the gate electrodes of transistors 216, 218 together receive the Load 2signal.

The Load 1 and Load 2 signals are provided from column address controllogic circuit 76 (FIG. 3) and more particularly from the load multiplexcontroller 134 thereof (FIG. 5). Lines 222 and 228 are coupled to theinput of inverter 142, the output of inverter 144, to each other, and tothe gate electrode of one of a group of four output transistors 230,232, 234, and 236 which form a dedicated data output (read) port. Inparticular, line 222 is coupled to the gate electrode of transistor 232(and hence sees a high impedance). Lines 224 and 226 are coupled to theoutput of inverter 142, the input of inverter 144, to each other, and tothe gate electrode of output transistor 236.

The sources of transistors 232 and 236 are coupled to ground potential(Vss). Their drain electrodes are coupled to the sources of transistors230 and 234 respectively. The gate electrodes of transistors 230 and 234are both connected to a decoded line 61, which preferably conducts theappropriate column read signal Yr. The drains of 230 and 234 arerespectively coupled to bus 57 to carry signals d_(out) and /d_(out).

FIG. 7 shows where several of the circuits described herein can bearranged on an integrated circuit. FIG. 7 shows a plurality of DRAMsubarrays 40. Illustratively each such subarray is 128 by 2 k. Adjacenteach such subarray 40 is a plurality of corresponding sense amplifiers(“S.A.”) 44. Preferably there are 1 k of such sense amplifiers adjacentto the corresponding DRAM subarray. Also adjacent to the DRAM subarrayis a set of preferably 512 row registers. Located beside the set of rowregisters is preferably 1 of 256 column decoders (unnumbered). Thesecolumn decoders are part of circuit block 60 of FIG. 3.

Located beneath the DRAM subarray (in plan view) is 1 of 128 rowdecoders. Row decoders are part of circuit block 52 in FIG. 3. Adjacentthe row decoder is register control and address control circuitry, whichcorresponds to all of the FIG. 3 circuit blocks 72 and 76, and part ofcircuit blocks 52 and 60.

It will be seen that an EDRAM according to the preferred embodiment ofthe present invention integrates a plurality of static RAM type of cells(latches) connected via pass gates to the DRAM bit lines to be used forvarious functions, including functioning as a cache to accelerate accesstime. It is also useful to expand page mode read cycles over prechargeperiods and refresh periods.

In a standard DRAM, while /RAS is low, the device can cycle through thecolumn addresses and perform reads and writes at a much faster rate andcycle time than it would be able to do by cycling /RAS. That enhancementis referred to in the art as “page mode” or “static column mode.”Functionally speaking, the present invention in its preferred formprovides a device which, from the outside, looks much like a standardDRAM. However, it allows the maximum flexibility for usage of its rowregisters to hide precharges, hide refreshes, and accelerate accesses.To do that, a set of external pins is preferably assigned in a way (asset forth above) that looks somewhat similar to the functionality ofexternal pins on a standard DRAM. The external pins used for controlfunctions receive the following signals: the /RE signal, which iscomparable to /RAS on a standard DRAM; /CAL, which is comparable to /CASin a standard DRAM; and /WE which is comparable to /WE on a standardDRAM. However, further control pins are used to receive the controlfunctions /F, /S, and W/R which were described above.

An advantage of changing from a /CAS function to a /CAL function is thatthe device uses it preferably only as a column address latch signal. Itno longer has any function in output control nor as an internal refreshsignal. Responsibility for those functions is assigned to other signalsat other pins. For example, the /F signal is to replace one function ofthe standard /CAS pin as a “/CAS before /RAS” refresh indicator.

The output control is implemented through the /G signal which is shownat the top of FIG. 3 going into block 64. In the preferred embodiment,that is the only output control signal. So the /G, /F and /CAL pins withtheir respective signals collectively provide the functions that a /CASpin /CAS signal would have on a standard part.

Similarly, a standard part has a /RAS pin for receiving the row addressstrobe. This function is replaced by the /RE signal at the /RE pin. The/RE signal preferably does not have the disable function that thestandard /RAS signal would have had. On a standard part, when /RAS goeshigh, any page mode access must be terminated. On the preferred EDRAM,the row registers allow a user to continue a cage mode access throughprecharge periods which are indicated by /RAS high, and during /Frefreshes, which are comparable to a standard /CAS before /RAS refresh.Therefore, /RE does not have a power down or a complete part disablefunction that a standard /RAS pin would have. It is still used as a rowaddress latch and as a DRAM cycle initiator. The /S pin provides thepower down function that a standard /RAS pin would have provided (as oneof its several functions).

Operation of the Circuit

Refresh

Standard DRAM arrays have to be refreshed on a somewhat regular basisbecause of the leakage from the DRAM cells. On a standard device meansare provided to be able to do that without providing external addresses.A standard device commences its refresh cycle in response to thecombination of input signals where /CAS is low when /RE falls. At thattime, internal chip logic recognizes that combination of voltages at thecorresponding pins and generates an address internally that isindependent of what is provided on the address pins that are external tothe chip. The internal chip logic then activates the DRAM by driving aDRAM row signal to an active state. That allows the data stored in oneentire row of DRAM cells to be transferred onto the bit lines. Once thathas taken place, the sense amplifiers are activated to amplify thatsignal. In the course of amplifying that signal, it refreshes the stateof the DRAM cell, i.e., it drives the bit lines that are connected bythe active row to full logic states to be stored in the DRAM cells. Inthe process of doing that, it writes that state back into the selectedrow of DRAM cells. That is all that is necessary in order to execute arefresh for that row. Once that has been completed, the row can bedriven inactive again. The sense amplifiers then will be precharged totheir standby state, another row will be selected and refreshed, and soforth until the refresh cycle is completed.

The EDRAM according to the preferred embodiment also provides internalcircuitry to achieve refreshing, but it operates without using a /CASbefore /RAS sequence to signal such a function. The /F signal, whichpreferably is received at its own respective pin, is an externallyapplied control signal indicating that a refresh is necessary. Oneadvantage of this combination of signals is that page mode access (whichrequires the use of /CAL) can be executed during the refresh. Hence thepin that receives the /CAL signal, which preferably is a dedicated pin,is free to be able to do that, even while the DRAM refresh is takingplace. Hence, the /F pin is provided to decouple that function from the/CAS pin. Other than that, the refresh circuitry is fairly standard DRAMcircuitry and operates in like manner.

Row Register Access During Refresh

One key aspect in the operation of a device according to the presentinvention is that because there is data stored in the row registers, therow registers can be decoupled from the corresponding DRAM subarray.Therefore, while that refresh is taking place, those row registers cancontinue to provide output data to the output data buffers 64 in FIG. 3.

Essentially, the /RE signal is used to request access of any type to theDRAM subarrays. If /RE is not toggled, access is available to the rowregisters only. There are three main varieties of access to the DRAMsubarrays: (1) a refresh, (2) a read cycle, and (3) a write cycle. Ineach of these cases, the type of cycle requested is indicated to theEDRAM prior to the falling edge of /RE, which is the actual request foraccess to DRAM cells.

If /F is low prior to /RE falling, that indicates that the requestedaccess is a refresh access. During a refresh access, the row decoderaddress will be supplied from the refresh address counter 68. The DRAMwill be activated, the sense amplifiers 44 will be triggered, but thewrite and load multiplexer 48 will not be activated, so that the rowregisters are disconnected from the DRAM subarray and can be accessedfrom the outside of the chip in a read fashion. That is one of the majoradvantages of this invention. By toggling /CAL during this refresh, ormerely by providing column addresses during this period of time, readingin a fashion that looks very much like a page mode read in a standardDRAM can continue to be executed throughout the period of time that therefresh is taking place. The refresh is a fairly long cycle because itrequires access to the DRAM subarrays. In one embodiment, 35 nanosecondsmay be specified to access the subarray and another 25 nanoseconds toprecharge it before another access is available. The access to the rowregisters may take only 15 nanoseconds, e.g., and so there is a 60nanosecond dead time that a prior art part would suffer while performingthat refresh. During this refresh and precharge time, a standard partwould not provide access to any of the data because a standard partwould need to read data from its sense amplifiers. However, during arefresh, the sense amplifiers are busy doing the refresh and aretherefore not available to provide data to the outputs. In an EDRAMaccording to the present invention, however, data is taken from the rowregister 56 rather than from the sense amplifiers 44. Consequently, thedata in the row registers can be made continually available while thesense amplifiers are active doing the refresh.

Read Cycles

Two other types of /RE cycles are read and write type of /RE cycles.Henceforth, we will refer to a “user” to mean a CPU 30, a host system,or any other system that uses an EDRAM 34. When a user wants to executea read type of access to the DRAM array, this in essence means that thedata in the row registers is thought by the user not to be the datadesired to be read. If the desired data is already in the row registers,the user does not need to toggle /RE in order to read it. Driving /RE tothe active state means that the user thinks it needs access to the DRAMarray rather than only the row registers. If it thinks that the data itwants is already in the row registers, it can leave /RE sitting high(inactive) and continue to access the row registers in a page mode typeof cycle. The EDRAM user may simply provide a column address, and storeddata will come out (assuming /G is toggled low to activate outputcircuits).

Now, if the user has decided that the data it wants is not in the rowregisters, it is going to request access to the DRAM in a read cycle. Aread cycle as opposed to a write cycle, is indicated by the state of W/Rbeing low when /RE falls. This means that the user wants to take dataout of the DRAM. Since the EDRAM permits read only via row registers,this means that data is to be read from the addressed DRAM cell andloaded into the row registers. The device responds as follows. Initiallyit confirms that the requested data is not already in the row registers.Internally, comparator 108 (FIG. 4) looks at the row address provided bythe user and determines whether the data is already in the rowregisters. The last read row latch 104 for the subarray corresponding tothe address given by the user is where the EDRAM will have stored theaddress of the previously loaded data. Comparator 108 will compare the“last read row” (LRR) address with the address on the input pads todetermine whether or not the data which the user requests to be loadedis, in fact, already loaded. If the requested data is found to have beenalready loaded, then the device will abort the requested access to theDRAM subarray and simply output the data that it had already loaded inthe row register. This can be done very quickly, e.g. in 15 nanoseconds,because this is essentially a page mode type of access to the rowregister access, and no access to the DRAM is necessary.

The benefit of operating in this way is that even though EDRAM 34 knowsthat the user thinks the data it wants is not in the row register, EDRAM34 checks to find out. If the data is there, then the EDRAM shortens thecycle. One may think this would be disadvantageous because the usershould already know that it does not need to toggle /RE. However, ittakes the user a certain amount of time to do such a comparisonexternally. So, the EDRAM preferably will allow the user to assume thatthe desired data is not in the row registers and will accelerate theread out if it is there. That way, the user does not have to make thatdetermination before it toggles /RE. This results in faster systemoperation.

Hence, in a read hit, if a /RE active read cycle is executed to a rowaddress that matches the last row read address (LRR), the /RE cycle isinternally terminated, independent of the external state of the /REsignal, and data becomes valid at the DQ pins after a column addressaccess time or a “column address latch high to data valid time,”whichever is greater.

Read Miss

Another type of cycle on an active /RE signal is a genuine read miss. Ona read miss, the comparator on FIG. 4 determines that in fact the useris correct and the data that it wants is not already loaded into the rowregister 56. On that type of cycle, the DRAM portion of the EDRAM willbe activated. The row decoder and address latch 52 on FIG. 3 willoperate to drive a DRAM word line high. The data from the (decoded) rowof DRAM cells will be loaded onto the bit lines 45, and thecorresponding sense amplifiers 44 will be triggered in the same fashionas they were on the refresh cycle discussed above.

Once sense amplifiers 44 have substantially latched and driven the bitlines 45 to the state indicated by the data in the addressed DRAM cells,a selected one of the two load lines 80 in FIG. 3 will be activated. Theactivation of a load line will cause the data that has been latched bythe sense amplifiers to be transferred into the row registers, therebyoverwriting the prior data which had been latched there. Similarly, thehit/miss determination (on line 75) will signal the last read row latch104 (corresponding to the DRAM subarray) in FIG. 4 to latch the addressthat is currently on the pads so that future comparisons for thatsubarray will compare to the address for which the data has now beenloaded into the row registers. This cycle takes illustratively 35nanoseconds because it is an access to the DRAM array. After that 35nanosecond time, data is made available to the output data buffers 64from the row registers 56. Once that has been done, additional columnaddresses can be supplied at a 15 nanosecond cycle rate in much the samefashion as the standard page mode.

Precharge During Read

During a read, the externally-applied /RE signal can go high, and theDRAM subarray can be precharged without terminating that page mode. When/RE goes high, first all load selection lines 80 are turned off, therebydecoupling the row registers 56 from the DRAM subarrays 40. This allowsthe row registers to continue supplying data to the output data buffers64 while the DRAM subarray is being deactivated. The row decoder is thendeactivated so that the word lines are driven inactive and the data istherefore kept in DRAM cells. The sense amplifiers are then prechargedand the DRAM subarray is put into a standby state.

Write Cycles

The third type of /RE cycle is a write cycle. For write cycles, the W/Rpin is driven high prior to the falling edge of the /RE signal on the/RE pin. The write enable signal /WE on the /WE pin is also activated.An active signal at the /RE pin indicates that the user has requestedaccess to the DRAM subarray, and a high signal at the W/R pin indicatesthat the user wishes to write. When this combination of input controlsignals exists, a write is signalled, and the EDRAM 34 knows that accessto the DRAM truly needs to occur. So, the EDRAM immediately activatesrow decoder 52 to decode the address provided on the external pins. Therow address control logic 72 will enable the row address enable signalon line 73 rather than the refresh address enable signal on line 74.That will allow the row decoders to latch the addresses A0-A10 providedon bus 71 rather than the addresses provided by the refresh counter 68on bus 69. (Column addresses are provided on the same bus 71 into columndecoder 60, but at a different time. Row addresses are considered validonly at the falling edge of /RE and slightly prior to it. Anything elseis considered a column address.) The active /RE signal indicates that infact a row address is on bus 71. The row decoders 52 now become activeagain, and a selected row of the DRAM is sensed by the sense amplifiers44. Whether this is a write hit or a write miss does not matter for thismuch of the cycle because the part knew that since a write is ordered,it must in fact access the DRAM subarray.

If the designated address is a write hit, once the sense amplifiers arelatched, EDRAM 34 will activate either the Load 1 or Load 2 signal.Whether it is Load 1 or Load 2 will be determined by the A10 row addressgoing into column address control logic 76 (see FIG. 3 and FIG. 5). In awrite hit, the purpose of activating a load signal is so that the datawritten into the DRAM subarray will also be written into the rowregisters 56. Write and load multiplexer 48 in FIG. 3, becomes activeand couples the bit line signal, via source-drain paths of transistors,to the latches of the row registers for the addressed subarray. Thispreserves data coherency between the DRAM and the row registers.

If it is a write miss, the DRAM subarray but not the row registers willbe written into. The row registers will continue to be decoupled fromthe DRAM cells by the inactivation by the write and load multiplexer 48.

Write-Per-Bit Function. In one implementation of an EDRAM, selectivemodification of individual I/O bits is possible. This is a“write-per-bit” feature which is useful in video applications and whenthe memory is used for parity bits. Mask bits and data bits aremultiplexed on the I/O pins via /RE and /WE. The “mask” capture occurson the assertion of /RE, and data capture occurs on the assertion of/WE. During the writing, the data is supplied by the user from thedata-in bus 83 in FIG. 3.

More particularly, data is provided at two different times. On thefalling edge of /RE, the data pins are monitored to determine what wecall “mask data.” Mask data is latched in the mask latch 84. Then, onthe falling edge of /WE, the data to be written to the part is latchedinto data latch 88. That is why /WE is shown as an input to the datalatch and /RE is shown as an input to the mask latch. When there is acommon low of the /WE pin and the /CAL pin, the actual write will beexecuted to the part (subject to an exception discussed below). Once the/WE and /CAL pins are both low, the data mask circuit 92 takes the datafrom the data latch 88, and takes the mask data from the mask latch 84.Any of the four bits latched can be masked (not written) according thedata in the mask latch.

The purpose of masking data is as follows. Suppose that the system isconfigured to have a four bit input, but the user really only want towrite one of those four bits. Many standard parts cannot accommodatethis because there is no way for the chip to refuse data being inputted.To have such a facility, the user needs a way to tell the EDRAM thatalthough data will be provided on all four inputs, the EDRAM is toignore the data on three of them. That is achieved by the mask latch 84on this part. On the falling edge of /RE (mask latch data), any databits that are high will be masked, i.e., not written by the part. Anybits that are low on the falling edge of /RE will be not ignored by thepart and will be considered valid write data (when /WE becomes active).

Although a decoder 82 is shown in FIG. 3, the three circuits 82, 84, and88 are not used simultaneously. There is no need for the “1 of 4”decoder 82 in a 4-bit part. If the part is to be a by-4 with the writeper bit capability, i.e., the ability to mask input data, then masklatch 84 will be active, data latch 88 will be active, but decoder 82going into the data mask 92 will be inactive. If the part is a by-4without write per bit, mask latch 84 will be inactive and bits willnever be masked. However, if the part is a by 1, then mask latch 84 isinactive, data latch 88 is active, but all four data latches get thesame bit from data-in bus 83 and the 1 of 4 decoder 82 determines whichof those four bits is useful and which are not. The other three will allbe masked. The part can be made to look like a by-1, when internally itis a by-4, by simply masking three of the input bits, based on the stateof the A9 and A10 column addresses (which are inputs to decoder 82). Thefour bits from data mask 92 are then provided to data select circuit 96,the purpose of which is to determine which of the possible bits are tobe written by the four bits provided by data mask 92.

FIG. 6 is shown for a single data-out bit and two data-in bits. A givensubarray has an output bus width of two bits and an input bus width offour bits. In large scale integration, of course, FIG. 6 is repeatedmany times, yet each of the many subarrays preferably will have only twodata-out bits and four data-in bits. If there are 1,064 columns in onesubarray, there are preferably 512 FIG. 6 circuits connected to that onesubarray. Each subarray preferably activates two FIG. 6 circuits atonce. There are 512 row register bits that go into 256 pairs of FIG. 6circuits, and one pair of those will be selected by the column decoder.Therefore, two d_(out) bits will be active at once (for outputting) ortwo pairs of the data-in bits (for writing).

In the preferred embodiment, two DRAM subarrays will always be accessedat the same time so that the four bits coming out of data mask circuit92 of FIG. 3 will actually be fed to different subarrays of the chip. Sothe four bits on bus 94 will actually go to two different data selectblocks 96. Preferably a given data select block 96 actually receivesonly two bits, and that is why bus 94 in FIG. 3 is marked for 2 bits.The data select block 96 has a four bit output bus 97, shown on FIG. 6as DIN0 and DIN1. Signals DIN2 and DIN3 would be inputted on a FIG. 6circuit directly adjacent to this one. The FIG. 6 circuits are activatedin pairs. The data select circuit 96 uses the A10 (row) signal to selectwhether to activate DIN0 or DIN1 for a given FIG. 6. Only one of the twowill ever be active at any given time; the other will always be masked.

On a 4 megabit part, there will be multiple iterations of many circuitsshown in FIG. 3. For example, these may be 16 DRAM subarrays 40 16multiplexers 48, and 16 row registers 56. Sense amplifiers 44 can beshared, so there will be multiple groups of blocks 44 but notnecessarily 16 of them (e.g., 9). Column decoder and address latch 60occurs 8 times, and each column decoder is shared between two rowregisters 56. The row decoder and address latch 52 occurs 16 times. Therefresh address counter 68 may occur 1 or more times on the chip, andbus refresh address 69 provides all row decoders 52 with the samerefresh address from the same counter. The row address control logic 72preferably occurs 4 times on the chip, each being shared between 4 rowdecoder address latch blocks 52. The column address control logic 76occurs 4 times in the same fashion. Data mask 92, data latch 88, andmask latch 84 occur 4 times on the chip, each shared between 8 DRAMsubarrays. Data select circuits 96 occur 16 times, one per multiplexer48. Decoder 82 for A9 and A10 column occurs only once on the chip.

To read out a whole row of data that had been loaded into the latches ofrow registers 56, assume that the load has taken place, has beenterminated, and that /RE is high. Perhaps the part has been on standbyfor a long time, but the data that the user wants is already in the rowregister. In that case, if the part was deactivated by virtue of the /Spin being high, we would drop the /S pin to activate the part and takeit out of a low power standby condition, provide a column address on theaddress bus 71, activate /G by driving it low (which activates theoutput circuitry), and wait for 15 nanoseconds for four bits of data tobe outputted. To read the next four bits, the user can simply change thecolumn address on the address bus 71 and wait another 15 nanoseconds.That next data would come out. That effect is very similar to a staticcolumn mode on a standard part except that the user never had toactivate /RAS and therefore never had to suffer a /RAS access timebefore that mode could be initiated.

To operate more like a page mode on a standard part, rather than an astatic column mode on a standard part, a user can choose to toggle /CALto latch the column addresses, rather than just holding the columnaddresses on the bus. If /CAL is being toggled, then as soon as /CALdrops, the user can change the address on the bus without that havingany effect on the part. When /CAL is high, the new column address wouldbe supplied. Then a user can continue to execute these 15 nanosecondcycles until it has cycled through all or as many of the row registerbits (which constitute one-half of the DRAM row) as desired to access.However, at no time was the user required to drop /RE, which iscomparable to a /RAS request to the DRAM.

Having read an entire row out of the row register, if the user now wantsto read the next row, the part will have to load data from that nextDRAM row into the row registers. Once that has been executed, readingout the data from the row register is exactly as described earlier. Theloading cycle consists of supplying a row address on the address bus 71,driving the W/R pin low to indicate a read cycle from the DRAM array,and toggling the /RE pin low to initiate that cycle. From the fallingedge of /RE, the DRAM subarray will be activated, and the data will betransferred into the row registers. That takes 35 nanoseconds. At theend of 35 nanoseconds, the data is in the row registers and can be readat a standard 15 nanosecond page mode access time in the same fashiondescribed earlier. Now at this point, /RE is still low because the useractivated /RE in order to initiate the load cycle of the DRAM data intothe row registers. On a standard part, as soon as /RAS goes high, accessto the data would be terminated and the part would be in what iscommonly referred to as the precharge portion of the cycle, which isdead time as far as the user is concerned. On this EDRAM, however, auser could terminate the /RE cycle after 35 nanoseconds and continueexecuting page mode reads from the row register. That would put the partin a mode identical to the mode discussed earlier where the data wasalready in the row register because now it is in fact already in rowregister. Unlike a standard part, once that precharge period has beencompleted, if the user wanted to execute an internal refresh of the DRAMarray, it could bring /F low, toggle /RE, execute the refresh, and stillcontinue to execute page mode reads from the row register in exactly thefashion discussed earlier.

Row Addresses vs. Column Addresses

When an address is put on bus 71 and /RE is high, the EDRAM does notknow whether it is column address or a row address. It treats thataddress as a column address and proceeds with the column access and inparallel with preparing to use it as a row address should it becomenecessary. If /RE never falls, the address will continue to be treatedas a column address until eventually that access is completed. However,if /RE falls, the use of the address in the column decoder is terminated(in exchange for the use of it in the row decoder). At that point thechip knows the user provided a row address, and needs to use thataddress in the row decoder and proceed with a DRAM access.

A DRAM access can be aborted in two ways. One is an illegal cycle. Forexample, if /CAL was low when /RE fell, that is illegal if /F was high.If an illegal cycle occurs, then the part effectively knows the userwanted to treat this as a row address, but then the user requested anillegal row cycle, and therefore the part will just ignore this addressaltogether. The other aborted access occurs in a read hit. On a readhit, access to the DRAM array is unnecessary, and is to be abortedbecause immediate access is given to the row register. Therefore, on thefalling edge of /RE, the row address is latched but is not used foranything because the DRAM array is left inactive. The address bus isrouted into the column decoder, and any address on the bus after /RE hasfallen is treated as a column address. So if the row address is stillthere, it will be treated as a column address and access to thatparticular row register will be granted.

The preferred EDRAM device uses what may be called a “look-ahead” methodand a positive row address set-up time. In a typical system, thesystem-wide address bus must be decoded in order to determine which ofseveral DRAMs or which particular memory device the user will speak to.The rest of the system address bus has been routed directly to thatmemory device. That system level decoding typically takes on the orderof 5 to 10 nanoseconds to determine which chip in the system needs to beactivated and to generate the corresponding /RE strobe. Therefore apositive address time occurs automatically in most systems even thoughmost chips do not require it. By using that period of time to determinein advance whether or not this will be a hit or a miss if a row strobeoccurs, and to determine whether the address should be treated as a rowaddress, the preferred EDRAM takes care of some overhead prior to /REfalling and therefore minimizes the amount of time required after /REfalls. It does so in a fashion that costs the system designer verylittle: he probably had those addresses there in advance because of thenature of his system design. So, when an address in on the bus, the partdoes not know whether it is a row address or a column address until /REfalls. In preparation for it possibly being a row address, the partproceeds to execute the necessary comparison by comparator 108 on FIG. 4and determines whether or not the address is a cache hit or miss. Thepart also will look at the control signals and determine whether a readcycle, a write cycle, or a refresh cycle is designated so that if /REdoes fall, all of those overhead control functions have already beenexecuted and the part can proceed immediately with the DRAM cyclewithout any additional delays.

If /RE does not fall, comparator 108 will have been prepared for it, butthe output of comparator 108 will simply be ignored with no harm done.In the meantime, that address will have been routed to the columndecoder and treated as column address. The address bus 71 going intoboth row address decoder 52 and column address decoder 60 allows thepart to prepare for the use of any given address as both a columndecoder address and a row decoder address at the same time, and if /REfalls, the part aborts the column route. If /RE does not fall, the rowroute never happens. The address is also routed simultaneously into therow address control logic, which is where that comparison takes place.

“Write Posting”

We mentioned that when /WE and /CAL were simultaneously low, that iswhen the write would occur. An exception to that is if the write occursvery soon after /RE falls. When /RE falls in a write cycle, the partmust always access the DRAM subarray. So when /RE falls, the partactivates the row decoder, senses the DRAM data with the senseamplifiers, waits for the sense amplifiers to get substantially latched,and then does or does not activate the Load 1 or Load 2 signals,depending on whether or not it was a write hit or a write miss. All ofthis must occur before we can actually write anything. All of that takes35 nanoseconds. System efficiency (i.e., the efficiency of a system suchas in FIG. 2) would be enhanced if the user could (a) alert the memory34 that this is a write cycle, (b) supply the data to write, (c) supplythe column address to write to, and (d) go on about its business withoutcontinuing to hold that information for the memory. The preferredembodiment EDRAM 34 allows this to occur via write posting.

After /RE falls, if the user puts the column address on the busimmediately and then drops /CAL and /WE, EDRAM 34 will latch the inputdata in data latch 88 and will latch the column address in the columnaddress latch (within circuit 60). It will then hold that informationuntil it has completely accessed the DRAM array, fired the senseamplifiers, and turned on any necessary load signals. At that time, withthe user long since gone to other activities, the memory can take thatdata that it latched and execute the function using an internally timedwrite pulse. The user does not need to provide that timing. This isunlike the standard art where the timing of that write pulse would haveto be provided by the user. Therefore, on a standard part, the usercannot simultaneously drop the column address strobe /CAS and the writeenable signal /WE until long after the read address strobe /RAS falls.

Another form of write posting is that on any write cycle, the memory canlatch data on the falling edge of /WE, independent of the state of /CAL.It can latch column addresses on the falling edge of /CAL, independentof the state of /WE. Therefore, data and addresses do not necessarilyhave to be on a user external bus at the same time. That provides fewerconstraints on system timing than the standard art, which requires thatboth data and addresses must be available at a single falling edge ofeither /CAL or /WE, whichever is the later of the two.

CONCLUSION

The EDRAM of the present invention produces tremendous speed withinnovative architecture yielding the optimal cost-performance solutionfor applications such as high performance local or system main memory.In most high speed applications, no wait state performance can beachieved without secondary SRAM cache and without interleaving mainmemory banks at certain system clock speeds, e.g. through 40 MHz.Two-way interleave will allow no wait state operation at higher clockspeeds, e.g. 50 MHz, without the need for a secondary SRAM cache. AnEDRAM outperforms the combination of conventional SRAM cache plus DRAMmemory systems by minimizing processor wait states for all possible busevents, not just cache hits. The combination of input data and addresslatching, 2K (illustratively) of fast on-chip SRAM type registers, andsimplified on-chip register (cache) control allows system levelflexibility, performance, and overall memory cost reduction notavailable with any other high density memory component on the market.

The architecture of the preferred embodiment EDRAM is similar to that ofa standard 4 Mb DRAM with the addition of 2 Kb of row registers (cache)and internal control which includes a last read row address latch and an11-bit comparator. The cache is integrated into the DRAM as tightlycoupled row registers. Memory reads always occur from the cache. Whenthe comparator detects a hit, only the cache registers are accessed andthe data therefrom is available in, e.g., 15 ns access/cycle time. Whena read miss is detected, the entire cache (row) is updated and data isavailable at the output all within a single access time of , e.g. 35 ns.Here also, subsequent reads within the new row will continue at 15 nsaccess/cycle time. In both cases, since the reads occur from the rowregisters, the DRAM precharge can occur simultaneously without degradingperformance. Having an on-chip refresh counter and an independentrefresh bus also allows the EDRAM of the present invention to berefreshed during row register (cache) reads.

Memory writes are always directed to the DRAM array. When appropriate,the on-chip address comparator will also activate a parallel write pathto the row registers. In this way, data coherency between row registersand DRAM array data is always ensured, with no system level overhead.Due to the quick 5 ns pulse and 5 ns precharge of the EDRAM, page modememory writes can be accomplished within a single column address cycletime. Changing rows during memory writes does not affect the contents ofthe cache except as appropriate for a cache write-through. This allowsthe system to return immediately to the cache which had been accessedjust prior to the write operation.

By integrating the cache as row registers and keeping on chip controlsimple, the EDRAM is able to provide enhanced performance without anysignificant increase in die size over standard slow 4 Mb DRAMs. Byeliminating the need for SRAMs and cache controllers, system cost, boardspace, and power are all reduced.

Further details of the structure and operation of an embodiment of thepresent invention are contained in the accompanying Attachment A.

It will be appreciated that the foregoing description is directed to apreferred embodiment of the present invention, and that numerousmodifications or alterations can be made without departing from thespirit or scope of the present invention.

1. An integrated circuit comprising: a row enable input for receiving asignal indicating that a row address is present at address inputs to theintegrated circuit; a row address latch for storing a row addresspresent at address inputs to the integrated circuit; an array of DRAMmemory cells organized in rows and columns; a set of sense amplifiersfor performing a DRAM row access by accessing the array of DRAM memorycells identified by the stored row address; a set of static registersseparate from said set of sense amplifiers, wherein subsets of thestatic registers are associated with individual rows in said array; acolumn address input for receiving a signal, during a DRAM row access,indicating that a column address is present at address inputs to theintegrated circuit; a column address latch for storing the columnaddress during a DRAM row access in response to the column addressinput; a write enable input for receiving a signal, during a DRAM rowaccess, indicating that data is present at data inputs to the integratedcircuit; a data latch for storing data in response to the write enableinput; and a write signal generator for generating an internal writesignal, after completion of the DRAM row access, to store the data inthe data latch to the array of DRAM memory cells in a locationidentified by the column address in the column address latch.
 2. Theintegrated circuit of claim 1 wherein each said subset set of staticregisters is arranged as a row and is capable of storing at least 32data bits from said associated subset set of sense amplifiers.
 3. Theintegrated circuit of claim 1 wherein each said subset of staticregisters is arranged as a row and is capable of storing at least 512data bits from said associated subset set of sense amplifiers.
 4. Theintegrated circuit of claim 1 wherein said array is arranged as aplurality of DRAM subarrays each having a respective plurality of bitlines, said set of static registers is arranged as a plurality of setsof registers corresponding in number to said plurality of DRAMsubarrays, each said subarray is coupled to only one respective set ofsaid registers, and each set of registers is coupled to receive andstore read data from only one corresponding DRAM subarray.
 5. Theintegrated circuit of claim 4 wherein each of said set of staticregisters is arranged as a row and is capable of storing at least 32data bits from its said corresponding DRAM subarrays.
 6. The integratedcircuit of claim 5 wherein each said DRAM subarray is positioned betweenits respective set of said registers and the said set of associatedsense amplifiers corresponding to said subarray.
 7. The integratedcircuit of claim 4 wherein each of said set of static registers isarranged as a row and is capable of storing at least 512 data bits fromits said corresponding DRAM subarray.
 8. The integrated circuit of claim7 wherein each said DRAM subarray is positioned between its respectiveset of said registers and the said set of associated sense amplifierscorresponding to said subarray.
 9. The integrated circuit of claim 1,further comprising a multiplexer coupling circuit interposed betweensaid set of sense amplifiers and said set of static registers, saidmultiplexer coupling circuit configured to selectively provide directdata transfer between said set of sense amplifiers and said set ofstatic registers multiplexed down by a factor of at least two.
 10. Anintegrated circuit comprising: an output buffer; a row enable input forreceiving a signal indicating that a row address is present at addressinputs to the integrated circuit; a row address latch for storing a rowaddress present at address inputs to the integrated circuit; an array ofDRAM memory cells organized in rows and columns; a set of senseamplifiers for performing a DRAM row access by accessing the array ofDRAM memory cells identified by the stored row address; a set of staticregisters separate from said set of sense amplifiers, wherein subsets ofthe static registers are associated with individual rows in said array;a column address input for receiving a signal, during a DRAM row access,indicating that a column address is present at address inputs to theintegrated circuit; a column address latch for storing the columnaddress during a DRAM row access in response to the column addressinput; a write enable input for receiving a signal, during a DRAM rowaccess, indicating that data is present at data inputs to the integratedcircuit; a data latch for storing data in response to the write enableinput; a write signal generator for generating a write signal, aftercompletion of the DRAM row access, to store the data in the data latchto the array of DRAM memory cells in a location identified by the columnaddress in the column address latch; a plurality of read only bit linesselectively coupled to said set of static registers and to the outputbuffer; a plurality of write only bit lines selectively coupled to saidset of sense amplifiers and configured so that all data to be written tosaid array is written to said sense amplifiers using said write only bitlines and not said read only bit lines, wherein said set of senseamplifiers and said set of static registers are respectively disposed onopposing ends of said array of DRAM memory cells, and wherein, inresponse to a data request including an address that identifies a row insaid array that corresponds to a subset of static registers, said readonly bit lines being coupled to the corresponding subset of staticregisters and said write only bit lines being coupled to thecorresponding subset of sense amplifiers such that data in thecorresponding subset of static registers is output to said output bufferusing the subset of sense amplifiers associated with the row identifiedby the data request address.
 11. The integrated circuit of claim 10wherein each said subset set of static registers is arranged as a rowand is capable of storing at least 32 data bits from said associatedsubset set of sense amplifiers.
 12. The integrated circuit of claim 10wherein each said subset of static registers is arranged as a row and iscapable of storing at least 512 data bits from said associated subset ofsense amplifiers.
 13. The integrated circuit of claim 10 wherein saidarray is arranged as a plurality of DRAM subarrays each having arespective plurality of bit lines; wherein said set of static registersis arranged as a plurality of sets of registers corresponding in numberto said plurality of DRAM subarrays; and wherein each said subarray iscoupled to only one respective set of said registers, and each set ofregisters is coupled to receive and store read data from only onecorresponding DRAM subarray.
 14. The integrated circuit of claim 13wherein each of said set of static registers is arranged as a row and iscapable of storing at least 32 data bits from its said correspondingDRAM subarrays.
 15. The integrated circuit of claim 14 wherein each saidDRAM subarray is positioned between its respective set of said registersand the said set of associated sense amplifiers corresponding to saidsubarray.
 16. The integrated circuit of claim 13 wherein each of saidset of static registers is arranged as a row and is capable of storingat least 512 data bits from its said corresponding DRAM subarray. 17.The integrated circuit of claim 16 wherein each said DRAM subarray ispositioned between its respective set of said registers and the said setof associated sense amplifiers corresponding to said subarray.
 18. Theintegrated circuit of claim 10, further comprising a multiplexercoupling circuit interposed between said set of sense amplifiers andsaid set of static registers, said multiplexer coupling circuitconfigured to selectively provide direct data transfer between said setof sense amplifiers and said set of static registers multiplexed down bya factor of at least two.
 19. The integrated circuit comprising: anoutput buffer; a row enable input for receiving a signal indicating thata row address is present at address inputs to the integrated circuit; arow address latch for storing a row address present at address inputs tothe integrated circuit; an array of DRAM memory cells organized in rowsand columns; a set of sense amplifiers for performing a DRAM row accessby accessing the array of DRAM memory cells identified by the stored rowaddress; a set of static registers separate from said set of senseamplifiers, wherein subsets of the static registers are associated withindividual rows in said array; a column address input for receiving asignal, during a DRAM row access, indicating that a column address ispresent at address inputs to the integrated circuit; a column addresslatch for storing the column address during a DRAM row access inresponse to the column address input; a write enable input for receivinga signal, during a DRAM row access, indicating that data is present atdata inputs to the integrated circuit; a data latch for storing data inresponse to the write enable input; a write signal generator forgenerating a write signal, after completion of the DRAM row access, tostore the data in the data latch to the array of DRAM memory cells in alocation identified by the column address in the column address latch; aplurality of read only bit lines selectively coupled to said set ofstatic registers and to the output buffer, a decoupling circuitconfigured to decouple said array from the said registers when data isbeing output from said registers to said output buffer via said readonly bit lines; and a precharging circuit coupled to the decouplingcircuit that is configured to precharge said array in preparation fortransferring data from said array and said sense amplifiers to saidregisters contemporaneously with the data being output from saidregisters to said output buffer via said read only bit lines whereinsaid set of sense amplifiers and said set of static registers arerespectively disposed on opposing ends of said array of DRAM memorycells, and wherein, in response to a data request including an addressthat identifies a row in said array that corresponds to a subset ofstatic registers, said read only bit lines being coupled to thecorresponding subset of static registers such that data in thecorresponding subset of static registers is output to said output bufferusing the subset of sense amplifiers associated with the row identifiedby the data request address.
 20. The integrated circuit memory chip asclaimed in claim 19, further comprising a refresh circuit coupled to thedecoupling circuit configured to refresh said array contemporaneouslywith the said data being output from said registers to said outputbuffer via said read only bit lines.
 21. The integrated circuit asclaimed in claim 19, further comprising a multiplexer coupling circuitinterposed between said set of sense amplifiers and said set of staticregisters, said multiplexer coupling circuit configured to selectivelyprovide direct data transfer between said set of sense amplifiers andsaid set of static registers multiplexed down by a factor of at leasttwo.
 22. An integrated circuit comprising: an output buffer; a rowenable input for receiving a signal indicating that a row address ispresent at address inputs to the integrated circuit; a row address latchfor storing a row address present at address inputs to the integratedcircuit; an array of DRAM memory cells organized in rows and columns; aset of sense amplifiers for performing a DRAM row access by accessingthe array of DRAM memory cells identified by the stored row address; aset of static registers separate from said set of sense amplifiers,wherein subsets of the static registers are associated with individualrows in said array; a column address input for receiving a signal,during a DRAM row access, indicating that a column address is present ataddress inputs to the integrated circuit; a column address latch forstoring the column address during a DRAM row access in response to thecolumn address input; a write enable input for receiving a signal,during a DRAM row access, indicating that data is present at data inputsto the integrated circuit; a data latch for storing data in response tothe write enable input; and a write signal generator for generating aninternal write signal, after completion of the DRAM row access, to storethe data in the data latch to the array of DRAM memory cells in alocation identified by the column address in the column address latch; aplurality of read only bit lines selectively coupled to said set ofstatic registers and to the output buffer; and an address comparatorconfigured to, in response to a data request including an address thatidentifies a row in said array that corresponds to a subset of staticregisters, signal the corresponding subset of static registers to outputdata using read only bit lines coupled to the corresponding subset ofstatic registers to said output buffer without access to said array ofDRAM memory cells, the data being output to said output buffer using thesubset of sense amplifiers associated with the row identified by thedata request address, wherein said set of sense amplifiers and said setof static registers respectively disposed on opposing ends of said arrayof DRAM memory cells.
 23. The integrated circuit of claim 22, furthercomprising a multiplexer coupling circuit interposed between said set ofsense amplifiers and said set of static registers, said multiplexercoupling circuit configured to selectively provide direct data transferbetween said set of sense amplifiers and said set of static registersmultiplexed down by a factor of at least two.
 24. A method comprising:receiving a row enable signal and row address at an integrated circuitmemory device and responsively storing the row address in a row addresslatch; accessing an array of DRAM memory cells identified by the rowaddress by triggering a set of sense amplifiers associated with thearray of DRAM memory cells; responsive to receiving a column addresslatch signal at the integrated circuit memory device during theaccessing of the array of DRAM memory cells, storing a column address ina column address latch; responsive to receiving a write enable signal atthe integrated circuit memory device during the accessing of the arrayof DRAM memory cells, storing data in a data latch; and, generating awrite signal within the integrated circuit memory device after accessingthe array of DRAM memory cells, and responsively writing the data storedin the data latch to the array of DRAM memory cells in a locationidentified by the column address from the column address latch.
 25. Themethod of claim 24, wherein the column address and the data are receivedsimultaneously at the integrated circuit.